Linear fresnel optic for reducing angular spread of light from led array

ABSTRACT

A light source may comprise a cylindrical lens, for example a cylindrical Fresnel lens, a linear array of light-emitting elements, the linear array aligned with and emitting light through the cylindrical Fresnel lens, wherein the cylindrical Fresnel lens reduces the angular spread of light in a widthwise axis of the linear array, the linear array spanning a lens length.

RELATED APPLICATIONS

The present application claims priority to U.S. Patent Application No. 61/624,974, filed on Apr. 16, 2012, the entire contents of which are hereby incorporated by reference for all purposes.

BACKGROUND AND SUMMARY

Ultraviolet light sources, such as mercury arc lamps and solid-state UV light sources comprising arrays of light-emitting diodes (LEDs) are commonly used for curing in coatings, inks, and adhesives in the imaging, printing, and telecommunication industries. LED technology is replacing traditional mercury arc lamps because they are more energy efficient, last longer, have lower operating temperatures, are safer and more environmentally friendly to use, can be manufactured more compactly, among other reasons.

LEDs and other types of light sources may be characterized as exhibiting a Lambertian or near-Lambertian emission pattern. Accordingly, one challenge with UV curing is providing a uniform irradiance of light across an entire target object or surface. In particular, curing of large two-dimensional surfaces may require manufacture of large light sources that are costly and cumbersome, or may require combining multiple light sources to provide irradiance over the target surface area. The inventor herein has recognized a potential issue with the above approaches. Namely, irradiance uniformity may be poor, especially near edges of emission patterns of individual light sources and at junctions between multiple light sources.

One approach that addresses the aforementioned issues includes a light source comprising a cylindrical lens, for example a cylindrical Fresnel lens, and a linear array of light-emitting elements aligned with and emitting light through the cylindrical Fresnel lens, wherein the cylindrical Fresnel lens reduces the angular spread of light in a widthwise axis of the linear array, the linear array spanning a lens length. Furthermore, the light source may comprise a housing, wherein a window may be mounted in a front plane of the housing, the window length spanning a front plane length, and wherein first and last light-emitting elements of the linear array are positioned adjacent to widthwise edges of the window, and wherein window sidewalls at the widthwise edges are aligned flush with the housing sidewalls. In this manner, emission pattern uniformity of the light source can be enhanced for an individual light source and across multiple light sources as compared to conventional light sources.

It will be understood that the summary above is provided to introduce in simplified form a selection of concepts that are further described in the detailed description. It is not meant to identify key or essential features of the claimed subject matter, the scope of which is defined uniquely by the claims that follow the detailed description. Furthermore, the claimed subject matter is not limited to implementations that solve any disadvantages noted above or in any part of this disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an example of a near-Lambertian emission pattern.

FIG. 2 is a schematic of an example of a regularly spaced linear array of light-emitting elements.

FIG. 3 is a schematic illustrating an irradiance pattern for the regularly spaced linear array of light-emitting elements of FIG. 2.

FIG. 4 is a plot showing a cross section of the irradiance pattern of FIG. 3.

FIG. 5 is a schematic of an example of a linear array of light-emitting elements with edge weighted spacing.

FIG. 6 is a schematic illustrating an irradiance pattern for the edge weighted linear array of light-emitting elements of FIG. 5.

FIG. 7 is a plot showing a cross section of the irradiance pattern of FIG. 6.

FIG. 8 is a plot of the irradiance profiles of FIGS. 4 and FIG. 7.

FIG. 9 is a plot of the irradiance profiles of FIGS. 4 and FIG. 7, and a plot of the irradiance profile of an edge weighted linear array with interior lensed LEDs.

FIG. 10 is a frontal view of an example light source.

FIG. 11 is a partial frontal view of two of the example light sources of FIG. 10 positioned side by side.

FIG. 12 is a partial side perspective view of the example light source of FIG. 10.

FIG. 13 is a frontal perspective view of the example light source of FIG. 10.

FIG. 14 is a schematic illustrating an example of a lighting system.

FIG. 15 is an example flow chart for a method of using a light source.

FIGS. 16A and 16C are perspective views of example cylindrical Fresnel lenses.

FIGS. 16 B and 16D are cross-sections of the example cylindrical Fresnel lenses of 16A and 16C, respectively.

FIG. 17 is a partial side perspective view of an example light source with a cylindrical Fresnel lens.

FIG. 18 is a cross-section of an example double cylindrical Fresnel lens.

DETAILED DESCRIPTION

The present description relates to a light source, method of using a light source, and lighting system for use in manufacture of coatings, inks, adhesives, and other curable workpieces. FIG. 1 illustrates an example of a near-Lambertian emission pattern for an LED light-emitting element. FIG. 2 shows a schematic depicting an example of a linear array of light-emitting elements arranged in a regularly spaced manner. FIGS. 3 and 4 illustrate an example of an irradiance pattern and a cross-sectional plot of the irradiance pattern for the regularly spaced linear array of light-emitting elements in FIG. 2. FIG. 5 shows a schematic depicting an example of a linear array of light-emitting elements, wherein the light-emitting elements are distributed with edge weighted spacing. FIGS. 6 and 7 illustrate examples of an irradiance pattern and a cross-sectional plot of the irradiance pattern for the edge weighted linear array of light-emitting elements in FIG. 5. FIGS. 8 and 9 are plots comparing the example irradiance profiles of FIGS. 4 and 7, and comparing the example irradiance profiles FIGS. 4 and 7 and that of edge weighted linear array with interior lensed LEDs. FIG. 10 is a frontal view of an example light source comprising a linear array of edge weighted light-emitting elements, while FIG. 11 illustrates an example of a partial frontal view of two light sources comprising edge weighted linear arrays of light-emitting elements arranged side by side. FIGS. 12 and 13 are a partial side perspective view and a frontal perspective view of the example light source of FIG. 10. FIG. 14 is a schematic of an example of a configuration for a light source and FIG. 15 is an example flow chart for a method of using a light source. Examples of multi-groove and single-groove cylindrical Fresnel lenses are depicted in FIGS. 16A, 16B, 16C, and 16D. FIG. 17 illustrates an example of a light source comprising a single-groove cylindrical Fresnel lens. A double cylindrical Fresnel lens is shown in FIG. 18.

Turning now to FIG. 1, it illustrates an emission pattern 100 for a near-Lambertian light source such as an LED type light-emitting element. The emission pattern illustrates that the angular spread of light originating from the near-Lambertian light source is broad and disperse, and the radiant intensity profile 110 is variable as the emission angle from the light source is varied from −90° to +90°. Accordingly, a surface illuminated by a near-Lambertian light source may not be uniformly irradiated with light.

FIG. 2 illustrates a simple schematic of an example of a regularly spaced 36 mm linear array 200 of ten light-emitting elements 220. Regularly spaced implies that the spacing 240 between each light-emitting element may be the same. The light-emitting elements may be mounted on a substrate 210, for example a printed circuit board (PCB).

FIG. 3 illustrates a plot 300 of an irradiance pattern at a fixed plane located 6 mm away from the regularly spaced linear array of LEDs in FIG. 2. The irradiance pattern of plot 300 may be generated using an optical simulation program such as Zemax. Curves 310, 320, 330, 340, 350, and 360 approximate lines of constant irradiance at a surface 6 mm away from the light source oriented perpendicular to the 90° emission angle of 1.80, 1.65, 1.30, 0.90, 0.40, and 0.20 W/cm² respectively. FIG. 3 illustrates the angular spread of light emitted from the linear regular-spaced array in a widthwise axis and a lengthwise axis. Irradiance from the regularly spaced array varies across the two dimensional pattern decreasing in intensity from the center of the pattern towards the periphery.

FIG. 4 shows a plot 400 of the cross section of the irradiance pattern of plot 300 taken along its major axis of symmetry, or along a centerline corresponding to the linear array. The irradiance profile 410 illustrates that the irradiance may be somewhat uniform in a central portion of the surface, but may decrease significantly towards the edges. For UV curing, a light source providing uniform irradiance at a target surface may provide uniform curing rates across the target surface. To achieve uniform cure rates, a surface may be irradiated using a light source providing an emission pattern where the irradiance is above a minimum threshold and below a maximum threshold across the target surface. For example, when the irradiance is below a minimum threshold, the cure rate may be slow and curing of the target surface may not be achieved. On the other hand, when the irradiance is above a maximum threshold, curing may proceed too rapidly causing overcuring which may damage the target surface. In general, when the difference between the maximum and minimum thresholds is smaller, more uniform curing rates are achieved. For example, a metric to evaluate uniformity may be defined using Equation (1):

Uniformity=(Maximum−Minimum)/Average (Maximum, Minimum)  (1),

wherein Maximum represents the maximum threshold and Minimum represents the minimum threshold irradiance corresponding to providing uniform curing rates. Equation (1) may then be solved for the minimum irradiance given a uniformity and maximum threshold irradiance:

Minimum=Maximum*(1−Uniformity/2)/(1+Uniformity/2)  (2)

For example, the case where the minimum threshold irradiance is equal to the maximum threshold irradiance corresponds to perfectly uniform irradiance. As a further example, using Equation (2), for a uniformity of 20%, and a maximum irradiance of 1.83 W/cm², the minimum irradiance is calculated to be 1.497 W/cm². In this manner, a useable length of the light output at a plane surface 6 mm from the evenly spaced linear array of LEDs of FIG. 2 may be determined from FIG. 4 to be 32.3 mm. The useable length corresponds to the length of the X-coordinate domain of irradiance profile 410 that is within box 420, wherein box 420 represents the X-coordinate values over which the emitted irradiance is between the minimum and maximum threshold values. Thus, over this calculated useable length, the irradiance uniformity may be 20% or less according to Equation (2).

Turning now to FIG. 5, it illustrates an example of a 36 mm linear array 500 of ten light-emitting elements (e.g., LEDs) with edge weighted spacing supported on a substrate 510, such as a PCB. The linear array may comprise a middle portion 516, which contains six LEDs 520 evenly distributed therein with a first spacing 540, and two end portions each comprising two LEDs 530 distributed therein with a second spacing 536. Additionally, a third spacing 560 may be provided between the middle portion 516 and end portions 518. First spacing 524 between light-emitting elements in the middle portion 516 may be larger than second spacing 536 between light-emitting elements in the end portions 518, and third spacing 560 may be smaller than first spacing 524, but larger than second spacing 536. As an example, the edge weighted linear array 500 may be manufactured with the same physical dimensions, may be supplied with the same amount power, and may use the same number and type of light-emitting elements (e.g. LEDs) as evenly spaced linear array 200. In other words, the linear arrays of light-emitting elements 500 and 200 may differ only in their spacing distribution of their light-emitting elements, linear array 200 employing even spacing between all ten light-emitting elements, and linear array 500 employing the above-described edge weighted spacing.

The edge weighted spacing illustrated in FIG. 5 is an example of an edge weighted linear array of light-emitting elements, and is not meant to be limiting. For example, edge weighted linear arrays of light-emitting elements may possess fewer or more than the ten LEDs illustrated in FIGS. 2 and 5. Furthermore, the middle portion of edge weighted linear arrays may comprise a larger or smaller number of LEDs and end portions may comprise a smaller or larger number of LEDs. Further still, the first spacing between light-emitting elements in the middle portion may be larger or smaller than the first spacing 524, the second spacing between light-emitting elements in the end portions may be larger or smaller than second spacing 536, and the third spacing between the middle and end portions may be larger or smaller than third spacing 560. However, edge weighted spacing implies that the second spacing between light-emitting elements in the end portions is smaller than the first spacing between light-emitting elements in the middle portion.

FIG. 6 illustrates a plot 600 of an irradiance pattern at a fixed plane located 6 mm away from the edge weighted linear array of LEDs in FIG. 5. The irradiance pattern of plot 600 may be generated using an optical simulation program such as Zemax. Curves 610, 620, 630, 640, 650, 660 and 670 approximate lines of constant irradiance at a surface 6 mm away from the light source oriented perpendicular to the 90° emission angle of 1.80, 1.65, 1.45, 1.30, 0.90, 0.40, and 0.20 W/cm² respectively. Irradiance from the edge weighted linear array varies across the two dimensional pattern, decreasing in intensity from the regions encompassed by curves 620 at the center of the pattern outwards towards the periphery.

Turning now to FIG. 7, it shows a plot 700 of the cross section of the irradiance pattern of plot 600 taken along its major axis of symmetry, or along a centerline corresponding to the edge weighted linear array. The irradiance profile 710 illustrates that the irradiance may be somewhat more uniform in a central portion of the surface as compared to the irradiance profile 410 of the evenly spaced linear array, but may also decrease significantly towards the edges of the profile. Using Equation (2) as above, for a uniformity of 20%, and a maximum irradiance of 1.83 W/cm², the minimum irradiance is calculated to be 1.497 W/cm². In this manner, a useable length of the light output at a fixed plane located 6 mm from the edge weighted linear array of LEDs of FIG. 5 may be determined from FIG. 7 to be 37.8 mm. The useable length corresponds to the length of the X-coordinate domain of irradiance profile 710 that is within box 720, wherein box 720 represents the X-coordinate values over which the emitted irradiance is between the minimum and maximum threshold values.

Turning now to FIG. 8, it illustrates a plot 800 comparing the irradiance profiles 810 and 820 from FIGS. 4 and 7 of the evenly spaced and edge weighted linear arrays respectively. As shown in FIG. 8, edge weighting the light-emitting elements, for example as in the linear array of FIG. 5, may provide an increase in the useable length light output of 5.5 mm relative to an evenly spaced linear array under the conditions of 20% uniformity corresponding to maximum and minimum threshold irradiances of 1.83 W/cm² and 1.497 W/cm² respectively at a fixed plane 6 mm from the light source. Box 830, corresponding to values of the irradiance between the minimum and maximum threshold irradiances, intersects irradiance profile 820 over a longer useable length as compared to irradiance profile 810. Thus by redistributing the light-emitting elements in an evenly spaced linear array to an edge weighted linear array, the uniformity of the light source can be increased while maintaining the dimensions (e.g., overall length) of the linear array and the power supplied to the light source.

Further improvements to the irradiance profile can be made by using LED's of different intensity. For example, higher intensity LEDs may be used in the middle portion (e.g., middle portion 516 in FIG. 5) of the linear array, while lower intensity LEDs may be used in the end portions. Increasing or decreasing the intensity of light from individual light-emitting elements can be achieved by using LEDs from different bins, wherein LEDs from different bins emit light with different intensities, using optical elements such as lenses to refract, reflect and/or diffract the light irradiated from individual light-emitting elements. For example, optical elements may be coupled to the light-emitting elements in the middle portion of the linear array to collimate the light and increase the irradiance of light from those elements. As another example, a diffuser may be coupled to the light-emitting elements in the end portions of the linear array to lower the irradiance of light irradiated from those elements. Furthermore, combinations of optical elements may be coupled to light-emitting elements in the middle and/or end portions to raise or lower the intensity of light irradiated from individual light-emitting elements. In the manners described above, edge weighting of linear arrays of light-emitting elements may thus be achieved through lensing, applying differential power, and by configuring the array with LEDs of different intensity, in addition to the edge weighted spacing previously described and illustrated in FIGS. 5.

Turning now to FIG. 9, it illustrates a plot 900 comparing the irradiance profiles 810 and 820 from FIGS. 4 and 7 of the evenly spaced and edge weighted linear arrays respectively. In addition, the irradiance profile 940 of an edge weighted linear array of LEDs similar to array 500, except wherein the four centermost LED elements are lensed to provide a 20% boost in their irradiance, is plotted. As shown in FIG. 9, coupling optical lens elements to the centermost LED elements enhances the uniformity of the linear array of light-emitting elements further, without supplying additional power or increasing the length of the linear array light source.

FIG. 10 illustrates a frontal view of a light source 1000 comprising an edge weighted linear array of twenty-seven light-emitting elements (e.g., LEDs) contained within a housing 1010. Light source 1000 may further comprise a front cover 1016 at the front plane of the housing 1010, a window 1020, and a plurality of fasteners 1030 for fixing the front cover to housing 1010. Housing 1010 and front cover 1016 may be manufactured from a rigid material such as metal, metal allow, plastic, or another material. The light-emitting elements may be mounted on a substrate (not shown), such as a PCB, and the front surface of the substrate may have a reflective coating or surface such that light irradiated from the light-emitting elements onto the substrate front surface is reflected towards the window.

Window 1020 may be transparent to light such as visible light and/or UV light. Window 1020 may thus be constructed from glass, plastic, or another transparent material. Window 1020 may be positioned approximately centrally with respect to the widthwise dimension of the front cover and a length of window 1020 may span the length of the front plane and the front cover 1016 of the housing 1010. Furthermore, window 1020 may be mounted so that its front face (1028 in FIG. 12) is flush with the front cover of the housing 1010, and so that window sidewalls (1086 in FIG. 12) are flush with the housing sidewalls (1018 in FIG. 13) and front cover sidewalls (not shown). In other words, window sidewalls, housing sidewalls, and front cover sidewalls are aligned in the same plane. Window 1020 may serve as a transparent cover for the edge weighted linear array of light-emitting elements contained within the housing, wherein light irradiated from the linear array is transmitted through window 1020 to a target surface, where for example, a curing reaction may be driven.

The linear array of light-emitting elements may be recessed under and approximately centered below window 1020 with respect to the lengthwise and widthwise dimensions of the window. Centering the linear array of light-emitting elements below the window 1020 may help to prevent irradiated light from being blocked by the lengthwise edges of the window where the window meets the front cover.

The edge weighted linear array comprises a middle portion 1052 between two end portions 1062. Middle portion 1052 comprises twenty-one evenly spaced light-emitting elements 1050 distributed with a first spacing 1054, while end portions 1062 each comprise two light-emitting elements 1060 with a second spacing 1064.

Furthermore, light source 1000 may comprise a third spacing 1068 between end portions 1062 and middle portion 1052, wherein the third spacing 1068 is smaller than the first spacing 1054 and larger than the second spacing 1064. Further still, light source 1000 may comprise a fourth spacing 1074 between the end portions 1062 and middle portions 1052.

The edge weighted spacing illustrated in FIG. 10 is an example of an edge weighted linear array of light-emitting elements, and is not meant to be limiting. For example, edge weighted linear arrays of light-emitting elements may possess fewer or more than the twenty-seven LEDs illustrated in FIG. 10. Furthermore, the middle portion of edge weighted linear arrays may comprise a larger or smaller number of LEDs and end portions may comprise a smaller or larger number of LEDs. Further still, the first spacing between light-emitting elements in the middle portion may be larger or smaller than the first spacing 1054, the second spacing between light-emitting elements in the end portions may be larger or smaller than second spacing 1064, and the third spacing between the middle and end portions may be larger or smaller than third spacing 1068. However, edge weighted spacing implies that the second spacing between light-emitting elements in the end portions is smaller than the first spacing between light-emitting elements in the middle portion.

The first and last light-emitting elements in the edge weighted linear array may be positioned directly adjacent to the window sidewalls 1086 of the window 1020. In this manner, the edge weighted linear array of light-emitting elements may span the length of window 1020 and front cover 1016 of housing 1010. As illustrated in FIG. 10, the window sidewalls 1086 may have a thickness wherein the distance from the first or last light-emitting element of the linear array to the external surface of the corresponding window sidewall may be one half or less the first spacing between middle portion light-emitting elements. In some examples a gap 1082 between the window sidewalls and the first and last light-emitting elements in the linear array may exist. Gap 1082 may allow for tolerance stackup and assembly of the light sources.

The light source 1000 may further comprise coupling optics or lensing elements (not shown) positioned between the linear array of light-emitting elements and the window. Coupling optics may serve to at least reflect, refract, collimate and/or diffract irradiated light from the linear array. Coupling optics may also be integrated with window 1020. For example, a diffuser or diffracting layer may be etched or laminated onto the back surface of window 1020 that faces the linear array. Further still, coupling optics may also be integrated into the front surface of window 1020 that faces the target surface. In some examples, coupling optics may further comprise a cylindrical lens, for example a cylindrical Fresnel lens (see FIG. 17), wherein the linear array of light-emitting elements may be aligned with and emit light through the cylindrical lens. In this manner, the cylindrical lens may reduce the angular spread of light in a widthwise axis of the linear array, thereby enhancing the uniformity of emitted light across a widthwise axis. In some examples the cylindrical lens may be a cylindrical Fresnel lens. Accordingly, the uniformity of emitted light in a widthwise axis (e.g., axis 580 in FIG. 5, and axis 680 in FIG. 6) may be enhanced as compared to the uniformity of emitted light in widthwise axis as compared to the irradiance patterns illustrated in FIGS. 4 and 6 for linear arrays of light-emitting elements emitting light through a window. Further still, coupling optics may further comprise a double cylindrical Fresnel lens (see FIG. 18) wherein two cylindrical Fresnel lenses are overlaid on top of one another such that enhanced collimating and focusing power for reducing the angular spread of light in a widthwise axis is achieved to a greater extent as compared with coupling optics comprising a single cylindrical Fresnel lens.

Turning now to FIG. 11, it illustrates a partial frontal view of two light sources 1110, 1120 arranged side by side. Light sources 1110 and 1120 may each be identical to light source 1000. Thus, light sources 1110, 1120 may each comprise an edge weighted linear array of light-emitting elements. Each linear array comprises light-emitting elements 1050 distributed with a first spacing 1054 in a middle portion, and light-emitting elements 1060 distributed with a second spacing 1064 in end portions. Furthermore, light sources 1110 and 1120 comprise a third spacing 1068 and a fourth spacing 1074 between light-emitting elements 1050, 1060 of the middle and end portions respectively. Third spacing 1068 may be larger than second spacing 1064 and smaller than first spacing 1054. As described above, edge weighting the linear array of light-emitting elements increases the useable length of light output from each light source.

Furthermore, first and last light-emitting elements in the end portions of light sources 1120 and 1110 respectively are positioned adjacent to window sidewalls 1086, wherein the window sidewalls 1086 span the length of the front plane of each light source housing. Positioning the first and last light-emitting elements in the linear arrays adjacent to window sidewalls 1086 may allow light sources 1120 and 1110 to irradiate light across the entire length of the window. Positioning the first and last light-emitting elements in the linear arrays adjacent to window sidewalls 1086 may comprise positioning the first and last light-emitting elements wherein there may be a small gap 1082 between the window sidewalls and the first and last light-emitting elements respectively.

Further still, the window sidewalls 1086 are flush with the sidewalls of the housings of light sources 1120 and 1110, the window and housing sidewalls extending backward perpendicularly from the front plane of the housing. Aligning the window sidewalls to be flush with the housing sidewalls may reduce spacing between and may maintain continuity of irradiated light across multiple light sources arranged side by side.

In this manner, the total distance from the last light-emitting element of a linear array of light source 1120 to the first light-emitting element of light source 1110 when positioned side by side may be the same or less than the first spacing between middle portion light-emitting elements. Accordingly, for a single light source, the distance from the last light-emitting element of the linear array to the external surface of the corresponding window sidewall may be one half or less the first spacing between middle portion light-emitting elements. Thus, light irradiated from light sources 1120 and 1110 arranged side by side may be more uniform as compared to light irradiated from conventional light sources arranged side by side.

FIG. 12 illustrates a partial side perspective view of the light source 1000 of FIG. 10, comprising front cover 1016, window 1020, fasteners 1030 and linear array of light-emitting elements 1090. Window 1020 comprises front face 1028 and window sidewalls 1086. Both window front face 1028 and window sidewalls 1086 are transparent.

Accordingly, a portion of light irradiated from end portion light-emitting elements adjacent to and near window sidewalls 1086 may be irradiated through window sidewalls 1086. Irradiation of light through window sidewalls 1086 of light sources may thereby reduce non-uniformities in irradiated light across multiple light sources arranged adjacently side by side as compared to conventional light sources arranged side by side. Window sidewalls 1086 are flush with the sides of front cover 1016 and housing sidewalls 1018 so that light sources can be placed side by side in a flush arrangement wherein a gap between the side by side light sources is reduced. To this end, fasteners 1030 mounted in housing sidewalls 1018 may also be recessed from the plane of housing sidewalls 1018 when fully secured. As previously described, aligning the window sidewalls to be flush with the housing sidewalls may reduce spacing between and may maintain continuity of irradiated light across multiple light sources arranged side by side.

Turning now to FIG. 13, it illustrates a perspective view of the example light source 1000 of FIG. 10. The light source comprises a housing 1010 containing a linear array of light-emitting elements, a window and a front cover 1016 at the front plane of the housing 1010, sidewalls 1018, and fasteners 1030. As illustrated, the light source 1000 may have a housing 1010 shaped as a square or rounded rectangular box. Other housing shapes where sidewalls extend backwards perpendicularly from the front plane of the housing and where light sources may be positioned flush when side by side may be used.

Turning now to FIGS. 16A and 16B, they illustrate perspective and cross-section views, respectively, of an example of a multiple-groove cylindrical Fresnel lens 1600. The multiple-groove cylindrical Fresnel lens in FIGS. 16A and 16B have sixteen grooves 1620, however in other examples, a multiple-groove cylindrical Fresnel lens may have fewer or more grooves. As an example, a multiple-groove cylindrical Fresnel lens may comprise 50 grooves. As a further example, a cylindrical Fresnel lens may comprise a single-groove cylindrical Fresnel lens 1602 having a single groove 1650 (e.g., a single prism), as illustrated by the perspective and cross-section views of FIGS. 16C and 16D, respectively. In general, as the number of grooves in a cylindrical Fresnel lens is increased, the thickness of the lens may decrease. In some examples, linear cylindrical Fresnel lenses may be manufactured from glass by a glass molding process, or optically transparent plastic. Glass lenses may be dimensionally more heat stable at higher heat loads or higher temperatures, such as temperatures above 120° C., as compared to plastic. However, glass cylindrical Fresnel lenses comprising a large number of grooves may be more difficult to manufacture precisely, as compared to plastic cylindrical Fresnel lenses because it may be difficult to achieve the fine sharp edges and points precisely by glass molding. For example, glass molded lenses may tend to have rounded edges and it may be more difficult to achieve multiple grooves of a fine pitch for lenses with large numbers of grooves. Manufacturing Fresnel lenses using plastic may allow achieving sharper prism ridges and finer prism pitch surfaces for Fresnel lenses with multiple grooves.

In order to collimate and reduce angular spread of emitted light in a widthwise axis 1604, the one or more cylindrical Fresnel grooves may be oriented parallel to the lengthwise axis 1608 of the light source. Furthermore, the cylindrical Fresnel lens may be oriented in a groove-in orientation, wherein the cylindrical Fresnel lens grooved surface 1630 faces toward the light source and the planar lens surface 1640 faces away from the light source, or a groove-out orientation, wherein the cylindrical Fresnel lens grooved surface 1630 faces away from the light source and the planar lens surface 1640 faces towards from the light source. The groove-in and groove-out orientation of the cylindrical Fresnel lens may impact the transmission efficiency of light through the cylindrical Fresnel lens. The geometry and shapes of the grooves of the cylindrical Fresnel lenses shown in FIGS. 16A, 16B, 16C, and 16D are for illustrative purposes and may not be drawn to scale. The cylindrical Fresnel lens may further comprise transparent lengthwise edges 1610. As an example, the cylindrical Fresnel lens may mount to the light source at the lengthwise edges 1610.

Turning now to FIG. 18, it illustrates a cross-section of an example of a double cylindrical Fresnel lens 1800, wherein two cylindrical Fresnel lenses 1820 and 1840 are overlaid on top of one another. In FIG. 18, each of the two cylindrical Fresnel lenses 1820 and 1840 are identical, with the same number and shapes of grooves, however, in other example double cylindrical Fresnel lenses the number and shapes of grooves of each of the lenses 1820 and 1840 may be different. Furthermore, in FIG. 18, each of the two cylindrical Fresnel lenses are oriented with a groove-in orientation, wherein incident light 1850 enters the grooved surfaces 1842 and 1822 and exits the planar surfaces 1844 and 1824 of cylindrical Fresnel lenses 1840 and 1820, respectively. In other example double cylindrical Fresnel lens configurations, the orientation of one or both Fresnel lenses may be oriented with a groove-out orientation with respect to the incident light 1850. In this manner, a double cylindrical Fresnel lens may achieve enhanced collimating and focusing power from a double cylindrical Fresnel lens configuration, and may reduce and collimate the angular spread of light in a widthwise axis to a greater extent as compared to a single cylindrical Fresnel lens. As a further example, more than two cylindrical Fresnel lenses may be stacked or overlaid to achieve enhanced collimating and focusing power for reducing and collimating the angular spread of light in a widthwise axis to a greater extent as compared to a single cylindrical Fresnel lens.

Turning now to FIG. 17, it illustrates a partial side perspective view of another example light source 1700. Light source 1700 may be similar to above-described light sources 1000, 1110 and 1120, and may further comprise coupling optics. For example, coupling optics of light source 1700 may comprise a cylindrical lens, for example cylindrical Fresnel lens 1720. Similar to light sources 1000, 1110, and 1120, FIG. 17 also shows light source 1700 including front cover 1016, fasteners 1030, housing sidewalls 1018, and the linear array of light-emitting elements 1090. Cylindrical Fresnel lens 1720 may comprise a single-groove or multiple-groove cylindrical Fresnel lens (e.g., cylindrical Fresnel lenses 16C and 16A respectively), wherein cylindrical Fresnel lens 1720 may comprise one or more grooves 1722 on a grooved surface 1724. Cylindrical Fresnel lens 1720 may have a groove-in orientation wherein grooved surface 1724 may face towards the light-emitting elements 1090 and planar surface 1728 may face away from the light-emitting elements 1090 as shown in FIG. 17. Alternately, cylindrical Fresnel lens 1720 may have a groove-out orientation, wherein grooved surface 1724 may face away from the light-emitting elements 1090 and planar surface 1728 of cylindrical Fresnel lens may face towards the light-emitting elements 1090. Cylindrical Fresnel lens 1720 may also comprise a double cylindrical Fresnel lens. Both planar surface 1728 and sidewalls 1786 of cylindrical Fresnel lens are transparent. Accordingly, a portion of light irradiated from end portion light-emitting elements adjacent to and near lens sidewalls 1786 may be irradiated through lens sidewalls 1786. Irradiation of light through lens sidewalls 1786 of light sources may thereby reduce non-uniformities in irradiated light across multiple light sources arranged adjacently side by side as compared to conventional light sources arranged side by side. Lens sidewalls 1786 may be flush with the sides of front cover 1016 and housing sidewalls 1018 so that light sources can be placed side by side in a flush arrangement wherein a gap between the side by side light sources is reduced. To this end, fasteners 1030 mounted in housing sidewalls 1018 may also be recessed from the plane of housing sidewalls 1018 when fully secured. As previously described, aligning the lens sidewalls 1786 to be flush with the housing sidewalls may reduce spacing between and may maintain continuity of irradiated light across multiple light sources arranged side by side. Furthermore, lens sidewalls 1786 may extend perpendicularly back from the front plane. In this manner, multiple light sources may be aligned flushly side by side wherein first and last light-emitting elements in the end portions of side by side light sources (e.g., similar to the arrangement of light sources 1120 and 1110 respectively in FIG. 11) are positioned adjacent to lens sidewalls 1786, wherein the lens sidewalls 1786 span the length of the front plane of each light source housing. Positioning the first and last light-emitting elements in the linear arrays adjacent to lens sidewalls 1786 may allow side by side light sources to irradiate light across the entire length of the lens. Positioning the first and last light-emitting elements in the linear arrays adjacent to lens sidewalls 1786 may comprise positioning the first and last light-emitting elements wherein there may be a small gap (e.g., gap 1082) between the window sidewalls and the first and last light-emitting elements respectively.

As another example, light source 1700 may further comprise a transparent window (not shown) mounted in a front plane of the housing and covering the front face of the cylindrical Fresnel lens 1720, wherein a front face of the window is aligned approximately flush with the front plane of the housing, and window sidewalls are aligned flushly with the housing sidewalls 1018. Aligning the lens sidewalls 1786 and window sidewalls to be flush with the housing sidewalls may reduce spacing between and may maintain continuity of irradiated light across multiple light sources arranged side by side.

Furthermore, the linear array of light-emitting elements 1090 may comprise an edge weighted linear array of light-emitting elements, as described above for light sources 1000, 1110, and 1120. Examples of edge weighted linear arrays of light-emitting elements and light irradiance patterns emitted therefrom are illustrated in FIGS. 5-9. Accordingly, the linear array may comprise light-emitting elements distributed with a first spacing in a middle portion, and light-emitting elements distributed with a second spacing in end portions. Furthermore, the linear array may comprise a third spacing and a fourth spacing between light-emitting elements, of the middle and end portions respectively. The third spacing may be larger than second spacing and smaller than first spacing. As described above, edge weighting the linear array of light-emitting elements may enhance the uniformity of emitted light in a lengthwise direction, and thereby may increase the useable length of light output from each light source while maintaining the dimensions (e.g., overall length) of the linear array and power supplied to the light source as compared to an evenly spaced linear array. Furthermore, the cylindrical Fresnel lens 1720 may enhance uniformity of emitted light in a widthwise axis, and thereby may increase the usable length of light output from each light source while maintaining the dimensions (e.g., overall width) of the linear array and power supplied to the light source as compared to a conventional light source that may not comprise emitting light through a cylindrical Fresnel lens.

In this manner, the total distance from the last light-emitting element of a linear array light source 1700 to the first light-emitting element of another light source 1700 positioned side by side may be the same or less than the first spacing between middle portion light-emitting elements. Accordingly, for a single light source, the distance from the last light-emitting element of the linear array to the external surface of the corresponding window sidewall may be one half or less the first spacing between middle portion light-emitting elements. Thus, light irradiated from multiple light sources 1700 arranged side by side may be more uniform as compared to light irradiated from conventional light sources with evenly spaced linear arrays of light-emitting elements arranged side by side.

In this manner, a light source may comprise a cylindrical Fresnel lens, a linear array of light-emitting elements, the linear array aligned with and emitting light through the cylindrical Fresnel lens, wherein the cylindrical Fresnel lens reduces the angular spread of light in a widthwise axis of the linear array. The light source may further comprise a housing, wherein a window may be mounted in a front plane of the housing, a window length spanning the length of the front plane, and a linear array of light-emitting elements within the housing. Furthermore, the linear array may span the window length, wherein first and last light-emitting elements of the linear array are positioned adjacent to widthwise edges of the window, and wherein window sidewalls at the widthwise edges are aligned flush with housing sidewalls. The window may comprise a front face and the window sidewalls, the front face flush with the front plane, and the window sidewalls extending perpendicularly back from the front plane.

The linear array of light-emitting elements may further comprise a middle portion in between two end portions, the linear array having only a single row of elements. The middle portion may comprise a plurality of light-emitting elements distributed over the middle portion with a first spacing throughout the middle portion, and each of the end portions may comprise a plurality of light-emitting elements distributed over the end portion with a second spacing throughout each end portion. The first spacing may be greater than the second spacing.

The linear array of light-emitting elements may further comprise a third spacing between the middle portion and each of the end portions, wherein the third spacing may be greater than the second spacing and less than the first spacing. The plurality of light-emitting elements in the middle portion may have a first irradiance, and the plurality of light-emitting elements in each end portion may have a second irradiance. Each of the plurality of light-emitting elements in the middle portion may comprise a higher intensity light-emitting element than each of the plurality of light-emitting elements in the end portions, and the first irradiance may be greater than the second irradiance.

Further still, the plurality of light-emitting elements in the middle portion may each comprises an optical element, each optical element increasing a first irradiance of its corresponding light-emitting element, wherein the first irradiance is greater than the second irradiance. Further still, the plurality of light-emitting elements in the end portions may each comprise an optical element, wherein the optical element decreases a second irradiance of its corresponding light-emitting element, and wherein the first irradiance is greater than the second irradiance.

Further still, the plurality of light-emitting elements in the middle portion may be supplied with a first drive current, the plurality of light-emitting elements in the end portions may be supplied with a second drive current, wherein the first drive current may be greater than the second drive current.

Referring now to FIG. 14, it illustrates a block diagram for an example configuration of lighting system 1400. In one example, lighting system 1400 may comprise a light-emitting subsystem 1412, a controller 1414, a power source 1416 and a cooling subsystem 1418. The light-emitting subsystem 1412 may comprise a plurality of semiconductor devices 1419. The plurality of semiconductor devices 1419 may be a linear array 1420 of light-emitting elements such as a linear array of LED devices, for example. Semiconductor devices may provide radiant output 1424. The radiant output 1424 may be directed to a workpiece 1426 located at a fixed plane from lighting system 1400. Furthermore, the linear array of light-emitting elements may be an edge weighted linear array of light-emitting elements, wherein one or more methods are employed to increase the useable length of light output at workpiece 1426. For example, one or more of edge weighted spacing, lensing (e.g. providing coupling optics) of individual light-emitting elements, providing individual light-emitting elements of different intensity, and supplying differential current to individual LEDs may be employed as described above.

The radiant output 1424 may be directed to the workpiece 1426 via coupling optics 1430. The coupling optics 1430, if used, may be variously implemented. As an example, the coupling optics may include one or more layers, materials or other structures interposed between the semiconductor devices 1419 and window 1464, and providing radiant output 1424 to surfaces of the workpiece 1426. As an example, the coupling optics 1430 may include a micro-lens array to enhance collection, condensing, collimation or otherwise the quality or effective quantity of the radiant output 1424. As another example, the coupling optics 1430 may include a micro-reflector array. In employing such a micro-reflector array, each semiconductor device providing radiant output 1424 may be disposed in a respective micro-reflector, on a one-to-one basis. As another example, a linear array of semiconductor devices 1420 providing radiant output 24 and 25 may be disposed in macro-reflectors, on a many-to-one basis. In this manner, coupling optics 1430 may include both micro-reflector arrays, wherein each semiconductor device is disposed on a one-to-one basis in a respective micro-reflector, and macro-reflectors wherein the quantity and/or quality of the radiant output 1424 from the semiconductor devices is further enhanced by macro-reflectors.

Each of the layers, materials or other structure of coupling optics 1430 may have a selected index of refraction. By properly selecting each index of refraction, reflection at interfaces between layers, materials and other structures in the path of the radiant output 1424 may be selectively controlled. As an example, by controlling differences in such indexes of refraction at a selected interface, for example window 1464, disposed between the semiconductor devices to the workpiece 1426, reflection at that interface may be reduced or increased so as to enhance the transmission of radiant output at that interface for ultimate delivery to the workpiece 1426. For example, the coupling optics may include a dichroic reflector where certain wavelengths of incident light are absorbed, while others are reflected and focused to the surface of workpiece 1426.

The coupling optics 1430 may be employed for various purposes. Example purposes include, among others, to protect the semiconductor devices 1419, to retain cooling fluid associated with the cooling subsystem 1418, to collect, condense and/or collimate the radiant output 1424, or for other purposes, alone or in combination. As a further example, the lighting system 1400 may employ coupling optics 1430 so as to enhance the effective quality, uniformity, or quantity of the radiant output 1424, particularly as delivered to the workpiece 1426.

As a further example, coupling optics 1430 may comprise a cylindrical Fresnel lens such as a linear cylindrical Fresnel lens for collimating and/or focusing the light emitted from the linear array 1420 of semiconductor devices 1419. In particular, a cylindrical Fresnel lens may be aligned with the linear array 1420, wherein emitted light therefrom is emitted through the cylindrical Fresnel lens and wherein the cylindrical Fresnel lens reduces the angular spread of light in a widthwise axis of the linear array, the linear array spanning a lens length. In some examples, a cylindrical Fresnel lens may be used in place of a window, such as window 1020, as shown in FIG. 17. The cylindrical Fresnel lens may be a single-groove lens or a multiple groove lens, and may also comprise a double cylindrical Fresnel lens (see FIG. 18) to further reduce the angular spread of emitted light in a widthwise axis as compared to a single cylindrical Fresnel lens.

Selected of the plurality of semiconductor devices 1419 may be coupled to the controller 1414 via coupling electronics 1422, so as to provide data to the controller 1414. As described further below, the controller 1414 may also be implemented to control such data-providing semiconductor devices, e.g., via the coupling electronics 1422. The controller 1414 may be connected to, and may be implemented to control, the power source 1416, and the cooling subsystem 1418. For example, the controller may supply a larger drive current to light-emitting elements distributed in the middle portion of linear array 1420 and a smaller drive current to light-emitting elements distributed in the end portions of linear array 1420 in order to increase the useable length of light irradiated at workpiece 1426. Moreover, the controller 1414 may receive data from power source 1416 and cooling subsystem 1418. In one example, the irradiance at one or more locations at the workpiece 1426 surface may be detected by sensors and transmitted to controller 1414 in a feedback control scheme. In a further example, controller 1414 may communicate with a controller of another lighting system (not shown in FIG. 14) to coordinate control of both lighting systems. For example, controllers 1414 of multiple lighting systems may operate in a master-slave cascading control algorithm, where the setpoint of one of the controllers is set by the output of the other controller. Other control strategies for operation of lighting system 10 in conjunction with another lighting system may also be used. As another example, controllers 1414 for multiple lighting systems arranged side by side may control lighting systems in an identical manner for increasing uniformity of irradiated light across multiple lighting systems.

In addition to the power source 1416, cooling subsystem 1418, and light-emitting subsystem 1412, the controller 1414 may also be connected to, and implemented to control internal element 1432, and external element 1434. Element 1432, as shown, may be internal to the lighting system 1410, while element 1434, as shown, may be external to the lighting system 1410, but may be associated with the workpiece 1426 (e.g., handling, cooling or other external equipment) or may be otherwise related to a photoreaction (e.g. curing) that lighting system 1410 supports.

The data received by the controller 1414 from one or more of the power source 1416, the cooling subsystem 1418, the light-emitting subsystem 1412, and/or elements 1432 and 1434, may be of various types. As an example the data may be representative of one or more characteristics associated with coupled semiconductor devices 1419. As another example, the data may be representative of one or more characteristics associated with the respective light-emitting subsystem 1412, power source 1416, cooling subsystem 1418, internal element 1432, and external element 1434 providing the data. As still another example, the data may be representative of one or more characteristics associated with the workpiece 1426 (e.g., representative of the radiant output energy or spectral component(s) directed to the workpiece). Moreover, the data may be representative of some combination of these characteristics.

The controller 1414, in receipt of any such data, may be implemented to respond to that data. For example, responsive to such data from any such component, the controller 1414 may be implemented to control one or more of the power source 1416, cooling subsystem 1418, light-emitting subsystem 1412 (including one or more such coupled semiconductor devices), and/or the elements 32 and 34. As an example, responsive to data from the light-emitting subsystem indicating that the light energy is insufficient at one or more points associated with the workpiece, the controller 1414 may be implemented to either (a) increase the power source's supply of power to one or more of the semiconductor devices, (b) increase cooling of the light-emitting subsystem via the cooling subsystem 1418 (e.g., certain light-emitting devices, if cooled, provide greater radiant output), (c) increase the time during which the power is supplied to such devices, or (d) a combination of the above.

Individual semiconductor devices 1419 (e.g., LED devices) of the light-emitting subsystem 1412 may be controlled independently by controller 1414. For example, controller 1414 may control a first group of one or more individual LED devices to emit light of a first intensity, wavelength, and the like, while controlling a second group of one or more individual LED devices to emit light of a different intensity, wavelength, and the like. The first group of one or more individual LED devices may be within the same linear array 1420 of semiconductor devices, or may be from more than one linear array of semiconductor devices 1420 from multiple lighting systems 1400. Linear array 1420 of semiconductor device may also be controlled independently by controller 1414 from other linear arrays of semiconductor devices in other lighting systems. For example, the semiconductor devices of a first linear array may be controlled to emit light of a first intensity, wavelength, and the like, while those of a second linear array in another lighting system may be controlled to emit light of a second intensity, wavelength, and the like.

As a further example, under a first set of conditions (e.g. for a specific workpiece, photoreaction, and/or set of operating conditions) controller 1414 may operate lighting system 1410 to implement a first control strategy, whereas under a second set of conditions (e.g. for a specific workpiece, photoreaction, and/or set of operating conditions) controller 1414 may operate lighting system 1410 to implement a second control strategy. As described above, the first control strategy may include operating a first group of one or more individual semiconductor devices (e.g., LED devices) to emit light of a first intensity, wavelength, and the like, while the second control strategy may include operating a second group of one or more individual LED devices to emit light of a second intensity, wavelength, and the like. The first group of LED devices may be the same group of LED devices as the second group, and may span one or more arrays of LED devices, or may be a different group of LED devices from the second group, but the different group of LED devices may include a subset of one or more LED devices from the second group.

The cooling subsystem 1418 may be implemented to manage the thermal behavior of the light-emitting subsystem 1412. For example, the cooling subsystem 1418 may provide for cooling of light-emitting subsystem 1412, and more specifically, the semiconductor devices 1419. The cooling subsystem 1418 may also be implemented to cool the workpiece 1426 and/or the space between the workpiece 1426 and the lighting system 1410 (e.g., the light-emitting subsystem 1412). For example, cooling subsystem 1418 may comprise an air or other fluid (e.g., water) cooling system. Cooling subsystem 1418 may also include cooling elements such as cooling fins attached to the semiconductor devices 1419, or linear array 1420 thereof, or to the coupling optics 1430. For example, cooling subsystem may include blowing cooling air over the coupling optics 1430, wherein the coupling optics 1430 are equipped with external fins to enhance heat transfer.

The lighting system 1410 may be used for various applications. Examples include, without limitation, curing applications ranging from ink printing to the fabrication of DVDs and lithography. The applications in which the lighting system 1410 may be employed can have associated operating parameters. That is, an application may have associated operating parameters as follows: provision of one or more levels of radiant power, at one or more wavelengths, applied over one or more periods of time. In order to properly accomplish the photoreaction associated with the application, optical power may be delivered at or near the workpiece 1426 at or above one or more predetermined levels of one or a plurality of these parameters (and/or for a certain time, times or range of times).

In order to follow an intended application's parameters, the semiconductor devices 1419 providing radiant output 1424 may be operated in accordance with various characteristics associated with the application's parameters, e.g., temperature, spectral distribution and radiant power. At the same time, the semiconductor devices 1419 may have certain operating specifications, which may be associated with the semiconductor devices' fabrication and, among other things, may be followed in order to preclude destruction and/or forestall degradation of the devices. Other components of the lighting system 1410 may also have associated operating specifications. These specifications may include ranges (e.g., maximum and minimum) for operating temperatures and applied electrical power, among other parameter specifications.

Accordingly, the lighting system 1410 may support monitoring of the application's parameters. In addition, the lighting system 1410 may provide for monitoring of semiconductor devices 1419, including their respective characteristics and specifications. Moreover, the lighting system 1410 may also provide for monitoring of selected other components of the lighting system 1410, including its characteristics and specifications.

Providing such monitoring may enable verification of the system's proper operation so that operation of lighting system 1410 may be reliably evaluated. For example, lighting system 1410 may be operating improperly with respect to one or more of the application's parameters (e.g. temperature, spectral distribution, radiant power, and the like), any component's characteristics associated with such parameters and/or any component's respective operating specifications. The provision of monitoring may be responsive and carried out in accordance with the data received by the controller 1414 from one or more of the system's components.

Monitoring may also support control of the system's operation. For example, a control strategy may be implemented via the controller 1414, the controller 1414 receiving and being responsive to data from one or more system components. This control strategy, as described above, may be implemented directly (e.g., by controlling a component through control signals directed to the component, based on data respecting that components operation) or indirectly (e.g., by controlling a component's operation through control signals directed to adjust operation of other components). As an example, a semiconductor device's radiant output may be adjusted indirectly through control signals directed to the power source 1416 that adjust power applied to the light-emitting subsystem 1412 and/or through control signals directed to the cooling subsystem 1418 that adjust cooling applied to the light-emitting subsystem 1412.

Control strategies may be employed to enable and/or enhance the system's proper operation and/or performance of the application. In a more specific example, control may also be employed to enable and/or enhance balance between the linear array's radiant output and its operating temperature, so as, e.g., to preclude heating the semiconductor devices 1419 beyond their specifications while also directing sufficient radiant energy to the workpiece 1426, for example, to carry out a photoreaction of the application.

In some applications, high radiant power may be delivered to the workpiece 1426. Accordingly, the light-emitting subsystem 1412 may be implemented using a linear array of light-emitting semiconductor devices 1420. For example, the light-emitting subsystem 1412 may be implemented using a high-density, light-emitting diode (LED) array. Although LED arrays may be used and are described in detail herein, it is understood that the semiconductor devices 1419, and linear arrays 1420 thereof, may be implemented using other light-emitting technologies without departing from the principles of the invention; examples of other light-emitting technologies include, without limitation, organic LEDs, laser diodes, other semiconductor lasers.

In this manner, a lighting system may comprise a power supply, a cooling subsystem, and a light-emitting subsystem. The light-emitting subsystem may comprise a housing, a window mounted in a front plane of the housing, a window length spanning a front plane length, and a linear array of light-emitting elements contained within the housing. The light-emitting subsystem may further comprise coupling optics, wherein the coupling optics comprise a cylindrical Fresnel lens mounted in a front plane of the housing. The linear array may be aligned with and emit light through the cylindrical Fresnel lens, wherein the cylindrical Fresnel lens reduces the angular spread of light in the widthwise axis of the linear array, the linear array spanning a lens length. Furthermore, the linear array may span the window length, wherein first and last light-emitting elements of the linear array may be positioned adjacent to widthwise edges of the window. Window sidewalls at the widthwise edges may be aligned flush with housing sidewalls, the window sidewalls extending perpendicularly back from the front plane.

Further still, the linear array of light-emitting elements may comprise a middle portion in between two end portions, the linear array having only a single row of elements. The middle portion may comprise a plurality of light-emitting elements distributed over the middle portion with a first spacing throughout the middle portion; and each of the end portions may comprise a plurality of light-emitting elements distributed over the end portion with a second spacing throughout each end portion, the first spacing greater than the second spacing.

The lighting system may further comprise a controller, including instructions executable to irradiate light from the light-emitting elements distributed over the middle portion having a first irradiance, and to irradiate light from light-emitting elements distributed over the end portions having a second irradiance, wherein the first irradiance is greater than the second irradiance. Furthermore, the coupling optics may further comprise first optical elements at each of the plurality of light-emitting elements in the middle portion and second optical elements at each of the plurality of light-emitting elements in the end portions. The cooling subsystem may comprise a heat sink with cooling fins conductively attached to a back surface of the linear array of light-emitting elements, and a cooling fan.

Turning now to FIG. 15, it illustrates a flow chart for an example method 1500 of irradiating a target surface. Method 1500 begins at 1510 where the dimensions of the target surface to be irradiated are determined. The target surface may comprise a portion of a surface or an entire surface. The target surface may further comprise a portion of a surface or object to be uniformly irradiated. For example, a first portion of the target surface may be cured with enhanced irradiance uniformity (e.g., uniformity determined using Equations (1) and (2)) and a second portion of the target surface may be cured with a non-enhanced irradiance uniformity. As an example, the first portion may be a central portion, and the second portion may be a periphery portion. In other examples the first and second portions may be a left and right side portion, and other apportioning schemes may be used as appropriate to the target surface to be irradiated.

Continuing at 1520, the number of edge weighted linear array light sources is determined. For example, one or a plurality of edge weighted linear array light sources arranged side by side may be used to irradiate the target surface. The number of light sources may be determined based one or more factors including the dimensions of the target surface to be irradiated, the irradiance pattern of the one or plurality of light sources, the dimension of the light sources, the power supplied to the light sources, and the target surface exposure time, among other factors. For example if the length of the target surface is very long, multiple light sources arranged side by side may be used to irradiate the entire length of the target surface. Furthermore, each of the one or plurality of light sources may comprise coupling optics, wherein the coupling optics include a linear array of light-emitting elements aligned with and emitting light through a cylindrical Fresnel lens. Further still, the coupling optics may comprise a double cylindrical Fresnel lens.

Next, method 1500 continues at 1530 where irradiance uniformity calculations may be performed. The uniformity calculations may be calculated using Equation (1) and (2) as well as knowledge of the irradiance patterns and irradiance profiles of the light sources. For example, irradiance patterns and irradiance profiles may be predetermined based on sensor measurements and/or optical simulations. Furthermore, using Equation (2), a maximum irradiance, and a predetermined uniformity level, a minimum irradiance intensity may be calculated for irradiance of a target surface at a fixed plane located at specific distance from the one or more light sources. Further still, performing uniformity calculations may include toggling one or more of the power supplied to the light source, the maximum irradiance emitted from the light source, the distance of the target surface from the light source, the irradiance exposure time, and other factors. For example, positioning the target surface at a fixed plane closer to one or more light sources may increase the area of the target surface meeting a specific irradiance uniformity, however, maximum irradiance levels at the closer fixed plane may exceed a maximum irradiance threshold. Consequently, the power supplied to the one or more light sources may be reduced to lower the maximum irradiance threshold while maintaining the same irradiance uniformity.

Method 1500 continues at 1540 where it is determined if irradiance uniformity is to be enhanced. For example, based on 1520 and 1530, it may be determined that irradiance uniformity is to be enhanced in order to irradiate a target surface with a predetermined irradiance uniformity within a predetermined irradiance exposure time. For example, a predetermined irradiance exposure time may correspond to a specified cure rate or curing time of a curing reaction at the target surface that is to be driven by the irradiated light. As another example, irradiation uniformity may be enhanced to provide uniform irradiance above a minimum irradiance threshold.

If it is determined that irradiance uniformity is to be enhanced, method 1500 continues at 1550, where the irradiance of middle portion light-emitting elements of the one or more edge weighted linear array light sources may be boosted. For example, boosting may comprise one or more of using higher intensity light-emitting elements (e.g., LEDs) in the middle portion of edge weighted the linear array light sources, using lower intensity light-emitting elements in the end portions of edge weighted the linear array light sources, integrating lens elements or other optical elements with the linear array light-emitting elements, or supplying light-emitting elements individually with different drive currents. For example, boosting irradiance of the middle portion light-emitting elements may comprise supplying additional drive current to the middle portion light-emitting elements, or supplying lower drive current to the end portion light-emitting elements. As another example, boosting irradiance of the middle portion light-emitting elements may comprise lensing the middle portion light-emitting elements to collimate irradiated light therefrom and/or supplying additional drive current to the middle portion light-emitting elements. Other methods and combinations of boosting the irradiance of middle portion light-emitting elements may be used to enhance irradiance uniformity.

Next, method 1500 continues at 1560 where one or a plurality of edge weighted linear array light sources are arranged side by side opposite a target surface at a fixed plane. The distance of the fixed plane from the one or more light sources may be determined based on one or more of 1520, 1530, 1540, and 1550 wherein arranging the target surface at the fixed plane opposite the one or more light sources can achieve uniform irradiance of the target surface.

Method 1500 continues at 1570 where power is supplied to the one or plurality of edge weighted linear array light sources to irradiate the target surface. Supplying power to the one or plurality of edge weighted linear array light sources may include supplying additional drive current to the middle portion light-emitting elements, or supplying lower drive current to the end portion light-emitting elements in order to enhance irradiance uniformity as in 1540 and 1550. Supplying power to the one or plurality of edge weighted linear array light sources may further comprise supplying power for a predetermined length of time or as prescribed by a controller control scheme. For example, one or more controllers (e.g., 1414) may supply power to the one or plurality of edge weighted linear array light sources to irradiate the target surface according to a feedback control scheme. Other examples of control schemes are described above in reference to FIG. 14. After 1570, method 1500 ends.

In this manner, a method of irradiating light may comprise irradiating light from a linear array of light-emitting elements, the linear array of light-emitting elements aligned with and emitting light through a cylindrical Fresnel lens, wherein the cylindrical Fresnel lens reduces the angular spread of light in a widthwise axis of the linear array. The linear array of light-emitting elements may comprise a middle portion in between two end portions, the linear array having only a single row of elements. The middle portion may comprise a plurality of light-emitting elements distributed over the middle portion with a first spacing throughout the middle portions, and each of the end portions may comprise a plurality of light-emitting elements distributed over the end portion with a second spacing throughout each end portion, wherein the first spacing is greater than the second spacing. A third spacing between the middle portion and each of the end portions may be greater than the second spacing and less than the first spacing.

Furthermore, the plurality of light-emitting elements in the middle portion may have a first irradiance, and the plurality of light-emitting elements in each end portion may have a second irradiance. Light irradiated from the plurality of light-emitting elements distributed over the middle portion may have a first intensity, and light irradiated from light-emitting elements distributed over the end portions may have a second intensity, wherein the first intensity is greater than the second intensity.

Further still, a first drive current may be supplied to each of the plurality of light-emitting elements in the middle portion, and a second drive current may be supplied to each of the plurality of light-emitting elements in the end portions, wherein the first drive current is greater than the second drive current, and the first irradiance is greater than the second irradiance.

Further still, the method may comprise one or more of reflecting, refracting, and diffracting light from each of the plurality of light-emitting elements in the middle portion via optical elements, wherein each of the plurality of light-emitting elements in the middle portion comprises one of the optical elements, and wherein the first irradiance is greater than the second irradiance. The method may further comprise one or more of reflecting, refracting, and diffracting light from each of the plurality of light-emitting elements in the end portions via optical elements, wherein each of the plurality of light-emitting elements in the end portions comprises one of the optical elements, and wherein the first irradiance is greater than the second irradiance.

It will be appreciated that the configurations disclosed herein are exemplary in nature, and that these specific embodiments are not to be considered in a limiting sense, because numerous variations are possible. For example, the above embodiments can be applied to workpieces such as inks, coated surfaces, adhesives, optical fibers, cables, and ribbons. Furthermore, the light sources and lighting systems described above may be integrated with existing manufacturing equipment and are not designed for a specific type of light engine. As described above, any suitable light engine may be used such as a microwave-powered lamp, LED's, LED arrays, and mercury arc lamps. The subject matter of the present disclosure includes all novel and non-obvious combinations and subcombinations of the various configurations, and other features, functions, and/or properties disclosed herein.

Note that the example process flows described herein can be used with various lighting sources and lighting system configurations. The process flows described herein may represent one or more of any number of processing strategies such as continuous, batch, semi-batch, and semi-continuous processing, and the like. As such, various acts, operations, or functions illustrated may be performed in the sequence illustrated, in parallel, or in some cases omitted. Likewise, the order of processing is not necessarily called for to achieve the features and advantages of the example embodiments described herein, but is provided for ease of illustration and description. One or more of the illustrated acts or functions may be repeatedly performed depending on the particular strategy being used. It will be appreciated that the configurations and routines disclosed herein are exemplary in nature, and that these specific embodiments are not to be considered in a limiting sense, because numerous variations are possible. The subject matter of the present disclosure includes all novel and non-obvious combinations and subcombinations of the various systems and configurations, and other features, functions, and/or properties disclosed herein.

The following claims particularly point out certain combinations and subcombinations regarded as novel and non-obvious. These claims may refer to “an” element or “a first” element or the equivalent thereof. Such claims are to be understood to include incorporation of one or more such elements, neither requiring nor excluding two or more such elements. Other combinations and subcombinations of the disclosed features, functions, elements, and/or properties may be claimed through amendment of the present claims or through presentation of new claims in this or a related application. Such claims, whether broader, narrower, equal, or different in scope to the original claims, also are regarded as included within the subject matter of the present disclosure. 

1. A light source, comprising: a cylindrical lens; a linear array of light-emitting elements, the linear array aligned with and emitting light through the cylindrical lens, wherein the cylindrical lens reduces an angular spread of light in a widthwise axis of the linear array, the linear array spanning a lens length.
 2. The light source of claim 1, wherein the cylindrical lens is a cylindrical Fresnel lens having only a single groove.
 3. The light source of claim 1, wherein the cylindrical lens is a cylindrical Fresnel lens comprising a double cylindrical Fresnel lens.
 4. The light source of claim 1, further comprising a housing, wherein a window is mounted in a front plane of the housing, the window length spanning a front plane length, and wherein first and last light-emitting elements of the linear array are positioned adjacent to widthwise edges of the window, and wherein window sidewalls at the widthwise edges are aligned flush with housing sidewalls.
 5. The light source of claim 4, wherein the linear array of light-emitting elements further comprises a middle portion in between two end portions, the linear array having only a single row of elements, wherein: the middle portion comprises a plurality of light-emitting elements distributed over the middle portion with a first spacing throughout the middle portion; and each of the end portions comprise a plurality of light-emitting elements distributed over the end portion with a second spacing throughout each end portion, the first spacing greater than the second spacing.
 6. The light source of claim 5, wherein a third spacing between the middle portion and each of the end portions may be greater than the second spacing and less than the first spacing.
 7. The light source of claim 6, wherein: the plurality of light-emitting elements in the middle portion have a first irradiance; the plurality of light-emitting elements in each end portion have a second irradiance.
 8. The light source of claim 7, wherein each of the plurality of light-emitting elements in the middle portion comprises a higher intensity light-emitting element than each of the plurality of light-emitting elements in the end portions, and wherein the first irradiance is greater than the second irradiance.
 9. The light source of claim 7, wherein the plurality of light-emitting elements in the middle portion each comprises an optical element, the optical element increasing a first irradiance of its light-emitting element, and wherein the first irradiance is greater than the second irradiance.
 10. The light source of claim 7, wherein the plurality of light-emitting elements in the end portions each comprises an optical element, the optical element decreasing a second irradiance of its light-emitting element, and wherein the first irradiance is greater than the second irradiance.
 11. The light source of claim 7, wherein: the plurality of light-emitting elements in the middle portion are supplied with a first drive current; the plurality of light-emitting elements in the end portions are supplied with a second drive current; and the first drive current is greater than the second drive current.
 12. The light source of claim 4, wherein: the window comprises a front face and the window sidewalls, the front face flush with the front plane, and the window sidewalls extending perpendicularly back from the front plane. 13-20. (canceled) 